NL1003470C2 - Purifying waste water from domestic or industrial source - Google Patents

Abstract

Waste water is purified in a cylindrical reactor (1 in figure) with a water supply(3 in figure), an outlet for treated water (10 in figure) and stirring means (5,6 in figure). Purification occurs with de-nitrifying, phosphate-removing bacteria suitable for removing oxygen-consuming biochemical components. The nature and concentration of the contaminants are measured on supply and discharge to regulate the degree of aeration of the water, depending on whether an oxidizing or reducing environment is required. Also claimed is the reactor to perform the method described above, provided with an air supply (7 in figure) near to the reactor base.

Description

Reactor and method for purifying waste water

The invention relates to a method for purifying waste water in a reactor consisting of a reservoir with a circumferential, for example cylindrical, outer wall, a supply pipe for the supply of waste water and a discharge for the discharge of processed water, wherein propellants are provided in the reactor for generating a flow in the waste water present in the reactor. The invention also relates to a reactor for carrying out such a method.

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It is known, for example, to purify domestic or industrial waste water using various chemical and biological sub-processes. In these sub-processes, the waste water is, for example, chemically purified by adding purifying chemicals that bind the pollutants in the water and, for example, allow them to settle. Increasingly, however, use is made of biological sub-processes in which micro-organisms purify pollutants from the waste water. These biological sub-processes serve in particular to remove nutrients, such as phosphates and nitrates, from the wastewater.

These biological sub-processes are performed, for example, under anoxic, anaerobic or oxic conditions.

Oxic sub-processes take place, for example, in aeration tanks. In these oxic sub-processes, nitrogen from the waste water is converted into nitrates and biochemical oxygen-consuming units, BODs, are removed from the waste water by connecting these BODs to the micro-organisms with the aid of oxygen. The nitrates formed are then removed again in an anoxic partial process with the help of micro-organisms. An anoxic partial process takes place in a low-oxygen environment, in which phosphate-accumulating bacteria can also absorb large quantities of phosphates from the waste water. These bacteria not only absorb the normal amount of phosphates 1 0 0 3 4 70 2 required for cell growth, but also absorb extra phosphate in the form of polyphosphates. In this way, phosphate is extracted from the wastewater and stored in sludge. Anaerobic partial processes also take place in an oxygen-poor environment that is additionally poor in nitrates. Because there is little oxygen in the anaerobic environment, reduction processes result in fatty acids that are absorbed by the bacteria while the phosphates are released by the bacteria to the water. The phosphate-rich water thus obtained can further be purified with the aid of chemicals that allow the phosphates to settle.

The number of times and the order in which the waste water goes through the sub-processes depends, among other things, on the degree and nature of the pollution of the waste water.

A drawback of the known purification installation is that there is always a limited number of reactors for each sub-process, each reactor being suitable for only one sub-process. For example, oxic reactors are equipped with an aeration system, while anoxic reactors must be equipped with a stirring system to prevent unwanted settling of sludge. Furthermore, for anoxic sub-processes, bacteria that thrive in an oxygen-poor environment must be used, while for the oxic sub-processes, bacteria that thrive in an oxygen-rich environment must be used. In the purification processes according to the known prior art, therefore, different bacterial species have been used hitherto for anoxic sub-processes than for oxic sub-processes.

The object of the invention is a purification process in which a reactor can be used for various sub-processes, wherein the purification process can be easily adapted to the nature of the contamination of the waste water to be purified.

This object of the invention is achieved by a method according to the type described in the preamble, in which the waste water is purified using denitrifying phosphate-removing bacteria or DPBs which are also suitable for removing biochemical, oxygen-consuming components, whereby the nature and degree of contamination are determined by means of measuring means, either of the incoming waste water to be purified or of the discharged, processed waste water, after which if an oxic sub-process is desired due to the nature of the pollution of aerating means the wastewater is aerated in order to obtain an oxic environment, while if an anoxic sub-process is desired due to the nature of the contamination, the aerating means are deactivated in order to obtain an anoxic environment in which a flow in the medium is carried out using propellants wastewater is generated.

It has been found that DPBs, or Denitrifying Phosphorus removing Bacteria, thrive in both an oxic and anoxic environment, where the respective sub-20 processes are efficiently run through these bacteria, whereby a high degree of purification can be obtained. By operating resp. deactivation of the aeration means can easily be switched from oxic to anoxic conditions and vice versa. Under anoxic conditions, a flow in the wastewater should be generated by the propellants to prevent activated sludge from settling.

The object of the invention is also achieved with a reactor for the purification of waste water, which reactor consists of a reservoir with a circumferential, for instance cylindrical, outer wall, a supply pipe for the supply of waste water and a drain for the disposal of processed water, in which propellants are arranged in the reactor for generating a flow in the waste water present in the reactor, the reactor being provided with a supply line for supplying air near the bottom of the reactor.

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This measure ensures that the reactor can be used both as an anoxic reactor and also as an oxic reactor. When used as an oxic reactor, the propellants are inactivated while the aeration plant is in operation. When used as an anoxic reactor, on the other hand, the propellants are in operation while the aeration installation is inoperative. Depending on the nature of the pollution of the wastewater, the reactor can now be used as an oxic reactor, respectively. as a 10 'anoxic reactor.

In a preferred embodiment of the reactor according to the invention, the reactor has a depth between 4 to 10 meters, for example about 7 meters, the diameter of the reactor being 5 to 10 times as great as the depth. The reactor is thus of relatively deep design, whereby only a limited cross-section is required to obtain a certain desired volume.

In a preferred embodiment of a reactor according to the invention, the supply for supplying the waste water is provided with means for measuring the redox potential. If the redox potential is high, this means that there are a lot of biochemical oxygen-consuming units or BODs in the wastewater and the reactor must be used as an oxic reactor. However, if the redox potential is relatively low, the reactor should be used as an anoxic reactor. The measuring means for measuring the redox potential can be arranged near the inlet of the waste water into the reactor. However, it is also possible to measure the redox potential at the beginning of the purification process as a whole, in which the waste water after measuring the redox potential first goes through a number of other sub-processes before being fed into the reactor according to the invention.

In a preferred embodiment of a reactor according to the invention, the propellants consist of one or more first thrusters for propelling the waste water in horizontal, tangential direction, and of a second thruster or stirring installation for propelling the waste water in vertical, upward direction, with the second thrust placed in the center of the reactor. In this way it is achieved that the waste water is mixed well, whereby swelling is prevented by means of the second vertical thrower, and the waste water is also mixed well in the middle of the reactor.

Preferably, the supply line for supplying the waste water to be purified discharges near the bottom of the reactor in a tangential direction. This further promotes the flow in tangential direction.

The discharge opening for discharging the processed waste water preferably consists of a vertical pipe in the center of the reactor, the open end of the pipe being placed just below the liquid level. The effluent flow thereby spirals from the side near the bottom of the reactor to the top in the center of the reactor via the vertical line or drowned from the reactor. The lead time of the wastewater in the reactor is therefore maximum.

Furthermore, the second vertical thrower preferably has a range such that the diameter of the sphere of influence of the vertical thrower, when the thrower has been activated and an anoxic environment prevails in the reactor, is substantially equal to about 0.5 to 2 times the distance between the liquid level in the reactor and the bottom of the reactor. In this way, swirling is effectively prevented.

The means for supplying the air preferably consist of a bubble aerator. Such an installation ensures a good distribution of air and sufficient oxygen uptake in the wastewater when the reactor is used as an oxic reactor. Moreover, such an installation can be realized in a simple and inexpensive manner.

The invention will be further elucidated with reference to the drawing. Herein shows:

Figure 1: In perspective reactor according to the invention with partly broken away drawn wall; Figure 2: Cross section of the reactor along the line II-II according to figure 1.

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Figure 1 shows a reactor 1 for purifying, for example, domestic or industrial waste water. The reactor 1 consists of a reservoir with a circumferential, cylindrical, outer wall 2, which is shown partly broken away in the drawing. The waste water 2 is supplied via a supply line 3. The feed pipe 3 opens into the reactor 1 at a location near the bottom 4 in a tangential direction with respect to the cylindrical wall 2. The flow coming from the feed 3 is therefore tangentially directed. The reactor contains DPBs, or Denitrifying Phosphorus removing Bacteria, which thrive in an oxic as well as in an anoxic environment. In an anoxic environment, these bacteria absorb phosphates and remove nitrates. Under oxic conditions, these 25 bacteria convert nitrogen into nitrates and remove biochemical oxygen-consuming units. First propellants 5, here designed as propellers, are arranged in the reactor for generating a flow in tangential direction. In order to prevent swirling and to obtain a good mixing of the waste water, a second pusher or stirring installation 6 is arranged in the middle of the reactor 1 for pushing the waste water in vertical, upward direction. The agitator 6 has such a range that the diameter of the sphere of influence when the agitator is activated and the anoxic environment in the reactor is equal to is approximately 0.5 to 2 times the distance between the liquid level in the reactor and the bottom of the reactor. The propellants are used under anoxic conditions to prevent unwanted sedimentation of sludge 1 0 0 3 4 70 7. The reactor is further provided with a bubble aeration installation 7 for supplying air near the bottom 4 of the reactor. When this aeration plant 7 is put into operation, oxic conditions are obtained in which biochemical oxygen-consuming units are removed by the bacteria and nitrogen is converted into nitrates.

After completing the partial processes carried out in the reactor 1 10 ', the processed water is discharged through a drowned spillway 8. This drowned spillway 8 consists of a vertical pipe 9 in the middle of the reactor 1, the open end of which 10 of the conduit is placed just below the liquid mirror.

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The reactor 1 is shown in cross-section along the line II-II according to figure 1 in figure 2. The open end 10 of the drowned spillway 8 is located just below the liquid level of the waste water 11.

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Such a reactor can be of relatively deep design, so that the reactor needs a limited cross-section to obtain a certain desired volume. In this way, a reactor can be realized with a depth between 4 to 10 meters, for example about 7 meters, the diameter being 5 to 10 times the depth. The active sludge content can consist of 3 to 10 kg per cubic meter of wastewater.

1003470

Claims (8)

A method for purifying waste water in a reactor consisting of a reservoir with a circumferential, for instance cylindrical, outer wall, a supply pipe for the supply of waste water and a discharge for the discharge of processed water, wherein propellants are arranged in the reactor for generating a flow in the waste water present in the reactor, characterized in that the waste water is purified using denitrifying phosphate-removing bacteria or DPBs which are also suitable for removing biochemical, oxygen-consuming components, whereby measuring means the nature and degree of contamination is determined either of the incoming waste water to be purified or of the discharged, processed waste water, after which if an oxic sub-process is desired due to the nature of the pollution, the waste water is aerated with the aid of aeration means in order to obtain an oxic environment, while if do If the nature of the contamination requires an anoxic sub-process, the aeration means are put out of operation in order to obtain an anoxic environment in which a flow is generated in the waste water by means of propellants. 2. Reactor for purifying waste water, which reactor consists of a reservoir with a circumferential, for instance cylindrical, outer wall, a supply pipe for the supply of waste water and a discharge for the discharge of processed water, in which propellants are provided for generating a flow in the waste water present in the reactor, characterized in that the reactor is provided with a supply line for supplying air near the bottom of the reactor. Reactor according to claim 2, characterized in that the reactor has a depth between 4 to 10 meters, for example about 7 meters, wherein the diameter of the 1 0 0 3 4 70 reactor is 5 to 10 times as large as the dLepte. Reactor according to claim 2 or 3, characterized in that the propellants consist of one or more first thrusters 5 for propelling the wastewater in horizontal, tangential direction, and of a second thruster for propelling the wastewater in vertical , upward direction, with the second thrust placed in the center of the reactor. 10 ' Reactor according to any one of claims 2 to 4, characterized in that the supply pipe for supplying the waste water to be purified opens out near the bottom of the reactor in tangential direction. 15 Reactor according to claim 5, characterized in that the discharge opening for discharging the processed waste water consists of a vertical pipe near the center of the reactor, the open end of the pipe being placed just below the liquid level. Reactor according to claim 6, characterized in that the second vertical thruster has a range such that the cross section of the sphere of influence of the vertical 2. thrower when the thrower is activated and an anoxic environment prevails in the reactor equals about 0.5 to 2 times the distance between the liquid mirror in the reactor and the bottom of the reactor. Reactor according to any one of claims 2 to 7, characterized in that the means for supplying the air consist of a bubble aerator. 1 0 0 3 4 70